Power Inverters in Electric Vehicles: Driving Efficiency and Performance

A device known as a power inverter converts the direct current (DC) power from the battery, which is used to run the electric motor, into alternating current (AC). The electric motors used in electric vehicles (EVs) are predominantly AC motors, requiring an inverter to convert the DC from the battery pack to the AC three-phase current that the motors operate on.

Moreover, inverters serve the purpose of controlling the speed, torque, and power output of the electric motor. This is accomplished by controlling both the frequency and amplitude of the AC signal to provide the vehicle with precise control over its dynamics and performance.

Energy storage systems, electronic systems, and efficiency improvements have given a new lease of life to electric vehicles. The power inverter is a core component that facilitates and enhances the use of EVs. It connects the battery to the electric motor, converting stored energy into usable energy for movement. This article explores the role of power inverters in enhancing the capabilities of the electric vehicle, their design principles, and their impact on power, efficiency, and vehicle dynamics, which also drive EV sales. For instance, in 2023, about 14 million new electric vehicles were registered worldwide, bringing the total number of EVs on the road to 40 million.

Electric Vehicles Sales, in Millions, China, 2022 to 2023

Source: IEA

Power Inverters Enhance Electric Vehicle Performance

Power inverters enhance EV performance in the following ways:

• Battery Charging Systems and Power Electronics
• Energy Management and Regenerative Braking

Let’s discuss each one in detail.

1. Battery Charging Systems and Power Electronics

An important aspect of electric vehicles (EVs) is the provision of rapid charging facilities for safe operation. This process is primarily managed by power electronics systems, which enable the control, incorporation, and management of electrical energy during charging.

Power electronics are critical in both onboard and offboard EV charging systems. For onboard chargers, AC/DC power electronic converters transform the mains AC voltage supplied to the charger into a DC voltage required for charging the vehicle battery. This involves rectification and further DC-DC conversion to achieve the desired voltage level and control the current to the battery. To avoid damaging the battery and ensure its longevity, the charging process is adjusted to the battery’s charge profile, typically involving multiple stages of constant voltage and current charging.

Off-board charging systems, such as DC fast-charging stations, are significantly enhanced by power electronics. Power electronic converters within these systems convert the input AC power supply to a high-voltage DC output capable of directly charging a vehicle’s battery without an onboard charger. Sophisticated control strategies manage the charge rate to prevent battery damage.

With the advent of bidirectional charging technology or Vehicle-to-Grid (V2G), power electronics have become even more advanced. These systems allow charging the vehicle and supplying power back from the vehicle battery to the house or grid during peak demand or blackouts. In wireless charging systems, power electronics manage power flow from the car’s battery to the primary coil, secondary coil, and the grid, ensuring efficient energy transfers while maintaining safety standards.

2. Energy Management and Regenerative Braking

Electric vehicles rely on energy management systems to handle complex power flows, utilizing power electronics to optimize efficiency. The primary objective is to allocate power from the battery to the electric motor, heating, ventilation, air conditioning (HVAC), and other auxiliary systems, while also recovering energy during regenerative braking.

Regenerative braking converts a vehicle’s kinetic energy, typically lost as heat during braking, into electrical energy stored in the battery for later use. This process extends the range of EVs and reduces wear on mechanical brakes. Power electronics, particularly inverters, are essential for controlling regenerative braking, ensuring stable operation and appropriate battery charging. Control algorithms within Electronic Control Units (ECUs) manage variables such as driver braking demand and battery charge levels.

Additionally, power electronics in the energy management system (EMS) optimize power distribution to various vehicle subsystems. For example, during high-speed driving or rapid acceleration, more power is directed to the drive motor, while at lower speeds, auxiliary systems like air conditioning may receive priority. DC-DC converters ensure proper voltage levels, and sophisticated algorithms maximize energy efficiency, driving range, and vehicle performance.

Case Study: Wireless EV Charging with WiTricity

Wireless charging of electric vehicle batteries is a groundbreaking application of power electronics by WiTricity. Using resonant inductive coupling based on Faraday’s law of induction, power is transferred from a charger embedded in the ground to a receiver on the vehicle. Power electronics manage the resonance of the transmitter and receiver, enabling efficient power transfer.

This technology offers cable-free charging convenience and has the potential for integration into public infrastructure, enabling seamless charging for parked or moving vehicles.

Conclusion

In conclusion, the power inverter is a fundamental component in enhancing electric vehicles. It is essential for speed and torque control, improves overall efficiency, and facilitates the conversion of DC from the battery to AC for the motor, among other functions that enhance the driving experience. The market for inverters is driven by advancements in semiconductor technology, increased power density, and improved control, delivering greater power and agility to EVs.

Developments in the design and technology of power inverters will shape the future of automotive electrification. As EV manufacturing grows, inverter technology will make next-generation EVs more efficient, cost-effective, and high-performing, incorporating new materials and advanced thermal management concepts.

In the era of digital technology, data centers serve as the building block for information technology infrastructure. When threats become more sophisticated, primitive security controls very often do not provide enough protection against unauthorized access to confidential information and secure protection of such critical systems. Data center security, however, is evolving thanks to these tools called artificial intelligence (AI) and machine learning (ML).  The use of AI and ML technologies in the detection, response, and prevention of global cyber threats and how the existing canvas of data center security is changing because of that. For instance, the expected costs of cyber attacks in 2022-2023 have been raised from US$8.44 trillion to US$11.50 trillion.

Figure 1:  Estimated Cost of Cybercrime, in USD Trillions, Global, 2022 to 2023

Source: Weforum.gov

How AI and machine learning are revolutionizing data center security are as follows:

• Enhanced Threat Detection
• Automating Security Operations
• Advanced Behavioral Analysis
• Real-Time Analysis and Decision-Making
• Adaptive Learning and Continuous Improvement
• Virtualization and Cloud Adoption

Let’s discuss each one in detail.

1. Enhanced Threat Detection

A major benefit that artificial intelligence and machine learning offer security for data centers is their ability to detect and respond to security threats within a very short period. Traditional methods are rule-based and signature-driven, which typically fall short of countering evolving threats. Artificial intelligence and machine learning can be trained on huge datasets to learn what does not fit, and what constitutes a threat.

Moreover, continuous learning techniques involve training algorithms on user behaviour, system activity or traffic, as well as their regular or abnormal use, making it possible to detect anomalous behaviour. Deviations from the created “normal” activity baseline are identified and drawn attention to, in order to flag potential security threats.

AI and machine learning-enhanced predictive analytics help in recognizing possible weaknesses even before they can be exploited. Such models can predict the likely vectors of attacks based on past information and this makes it possible to put in place mitigations beforehand.

2. Automating Security Operations

The scope of data center security includes a wide array of activities, ranging from constant vigilance and scrutiny to taking preventive measures and fixing issues. A significant proportion of these activities can rely on tools offered by artificial intelligence and machine learning which in turn enhances the output and precision.

By removing the drudgery and repetition associated with certain activities, human security teams are free and can devote their energies and resources to more strategic pursuits in the organization such as handling incidents and developing policies. Incorporating different security control systems for an optimized action is something that AI can do. To illustrate, if A.I. sees something that looks suspicious, it could carry out certain actions that have already been preset. For instance, it can cut off affected servers from the network, send notifications to the personnel in charge, or even launch a probe into the incident.

Moreover, AI systems can also be employed in the automatic classification and prioritization of security alerts thereby easing the burden on the IT personnel and ensuring that the pressing issues are addressed first. Hence, this capacity reduces the mean time to detect and the mean time to respond which are significant incident management measures improving the efficiency of the organization.

3. Advanced Behavioral Analysis

Advanced behavioural analysis modes are possible because of machine learning, and are important in the identification of insider threats. If internal threats – be they deliberate or unintentional – can be caused by external actors, these are the very targets that come from users with credibility which makes them more difficult to detect. ML algorithms are capable of persistently monitoring users so that any behaviours that could be harmful or deviate from acceptable standards are tracked and reported as anomalies.

Moreover, user and entity behaviour analytics employs AI systems to detect abnormal access frequency distributions and malicious actions. A system may for instance issue an alert or ask for additional authorization when an employee attempts to navigate to an area in the network that the employee has never accessed before. Using AI, there is a security network that can change as the risk levels are also changing. In this case, when a certain user is flagged for suspicious behaviour, an ML system could add extra layers of security such as requiring multi-factor authentication for that user.

4. Real-Time Analysis and Decision-Making

Due to artificial intelligence, which can analyze system logs and network traffic in real time, the security of data centers is set to change significantly. AI technology in data center security systems enables large volumes of data to be anonymized and analyzed in a short time to detect and mitigate possible threats without human assistance. AI algorithms can be used to analyze real-time network traffic patterns for data outflow or DDoS attack attempts.

Moreover, artificial Intelligence can automatically configure its network in such a way as to either block or redirect any incoming traffic that seems to pose a threat. Coupled with external threat intelligence feeds, such information can help them refresh their knowledge of the latest attack patterns. The information can be harnessed to adjust the defensive structures as well as the strategic military operations. In this way, there will be an assurance that the systems of the data center are not exposed to threats that are not new.

5. Adaptive Learning and Continuous improvement

The steady development of models is also the key objective of machine learning models. As more data is fed to the system, the AI is capable of recognizing more threats and minimizing the false positive rate. This is particularly important because new forms of attacks are consistently being developed in the ever-changing structure of data centers.

Moreover, attacks that can be classified as potential ones, help in improving the understanding of threats since ML systems are always fed with data. This helps attack detection algorithms to exploit the nuances of attack patterns that other algorithms might not find useful. Often due to the low level of accuracy of these systems, IT teams suffer from “alert fatigue” owing to the large number of false alerts. By understanding how to contrast typical innocuous behavioural deviations from genuine threats, ML models manage to reduce the number of false alarms and ensure that the security personnel only deal with real issues.

6. Virtualization and Cloud Adoption

As data centers increasingly adopt virtualization and cloud technologies, cybersecurity poses an additional challenge due to the enhanced attack surface. Here, where traditional defenses based on perimeters are no longer applicable, AI and ML come in handy. AI-enabled techniques secure dynamic workloads across EC2 instances regardless of their virtualization.

Further, AI-driven solutions can also inspect inter-communication between containers and VMs, identify any security gaps, and enforce security policies in real time. Access cloud resources in a more secure manner through the use of machine learning, which can, for example, identify unusual geographic locations or behaviours associated with a particular login. For instance, an alert or further authentication may be required when a user from a different region attempts to log into the data center.

In conclusion, data center security is being revolutionized by artificial intelligence through automated security management. With the use of artificial intelligence in data centers, the litany of mitigating risks associated with human errors, increasing efficiency and productivity and giving the benefit of monitoring and detecting threats in real-time are the core focal objectives. With the advancements in modern technology, it can be predicted that artificial intelligence will be more functional in automated security management systems. This will ensure that data centers remain secure and stand strong against cyber threats that keep on evolving.

Data center security is going to be dominated by AI-driven automated security management. Its capacity to offer proactive, scalable, and continuous security measures is crucial for safeguarding private information and preserving the integrity of vital systems. AI will become more crucial as data centers develop in order to protect their operations and guarantee their success in a quickly shifting digital landscape.

Wastewater is becoming an enigma in the sustainable development of society. The growing urban population of developing economies like India and China faces the serious challenge of water quality management and industrial wastewater treatment.

According to UNICEF, nearly two billion people live in countries where the water supply is inadequate. Half of the world’s population, especially in underdeveloped and developing economies in Africa and Asia, face water scarcity for clean drinking water for everyone. It is estimated that nearly 700 million people will have to relocate due to extreme water scarcity by 2030.

Due to global warming, there has been an increased frequency of droughts and famines across the globe, contributing to adverse water conditions. To save the environment from pollution and the harmful impact of untreated wastewater, it is important to introduce wastewater treatment technology. As we move towards a sustainable future, municipalities and industries are likely to adopt new water and wastewater treatment technologies.

The top innovations in water and wastewater treatment technology are:

• Water reuse and recycling
• Water treatment and circularity
• Per-and Polyfluoroalkyl Substances (PFAS) Destruction
• Thermal Hydrolysis
• Microbial fuel cells
• Membrane filtration
• Advanced Oxidation
• Nanofiltration
• Modular water treatment system
• Desalination

1. Water reuse and recycling

Water reuse and recycling revolve around treating wastewater to use again in the same location such as reusing residential sewage water and for irrigation of gardens in the societies. This approach reduces our dependence on freshwater resources and reduces the consumption of freshwater.

Companies such as Epic Cleantec provide onsite water reusing systems for commercial and large-scale buildings which reuse 95% of wastewater. This regenerative water reuse system can reduce utility costs and consumption of fresh water; it also has low operating costs and is sustainable.

According to the survey conducted by the company 70% of U.S. consumers prefer to spend money on companies that are using sustainable practices to provide green solutions.

According to the American Waterworks Association, the repairing and expanding of water infrastructure would require around USD 1 trillion in the next 25 years.

A few other notable companies that provide water reuse and recycling solutions include HydraLoop and Watersmart. Their shower solutions save both water and energy.

2. Water Treatment and circularity

Modern wastewater treatment technologies not only remove pollutants but also recover valuable resources such as nutrients, energy, and byproducts while treating the wastewater.

These wastewater treatment technologies focus on specific application areas where water is being treated. For instance, BioFiltro, a wastewater treatment company that uses its patented Biodynamic Aerobic (BIDA) system. The system uses worms and microbes to remove up to 99% of the contaminants in just a few hours and produces nutrient-rich worm castings.

Aquacycl, a wastewater management solution company, uses its patented modular Bio Electrochemical Treatment Technology (BETT) system to treat high biological oxygen demand (BOD) wastewater and generate electricity as a byproduct.

Gross-Wen Technologies and Water Warriors are also prominent companies that provide water treatment and circularity solutions.

3. PFAS Destruction

Per- and polyfluoroalkyl substances (PFASs) are chemicals that can be harmful to humans as their consumption can result in increased cholesterol levels, lower immunity, and cause kidney and testicular cancer. In 2009, the US Environmental Protection Agency (USEPA) established advisory limits on the presence of PFASs in drinking water. The most recent recommendation, which went into effect in June 2022, sets advisory limits of 2000 ppt of PFBS, 10 ppt of GenX chemicals, 0.02 ppt of PFOA, and 0.004 ppt of PFOA.

Several studies are being conducted to develop technologies that will remove PFAS contaminants from sources of drinking water. Reverse osmosis (RO), granular activated carbon (GAC), nanofiltration (NF), and ion exchange resin (IXR) are some of the technologies that eliminate or purify PFAS content from wastewater. Removal technologies do not completely remove or destroy PFASs, despite their demonstrated effectiveness in PFAS separation or adsorption. These are simply temporary measures of PFASs’ physical mass transfer (sequestration).

Even though several PFAS destruction technologies are still in the development stage, several companies have had breakthroughs in the research. Aclarity is one such company that has developed PFAS destruction technology. The company uses an Electrochemical Oxidation (EOx) process that involves the passage of an electrical current through a liquid solution to mineralize PFAS compounds on the anode surface. This technology requires low energy, and it is highly efficient.

374Water uses supercritical water oxidation, which is an advanced oxidation method that can treat a wide range of organic wastes. Similarly, Enspired Solutions uses a patented chemistry that uses unique chemistry coupled with ultraviolet light that stimulates a reaction to systematically disassemble PFAS molecules into water, fluoride, and simple carbon compounds.

4. Thermal Hydrolysis

Thermal hydrolysis is a process technology that anaerobically digests wastewater. Sewage sludge and other moist organic wastes are subjected to high temperatures and pressures during the process of thermal hydrolysis. It works like that when you cook using steam.

At the full scale, site-specific variables such as sludge type (wastewater treatment plant configuration, aeration sludge age, industrial loads); anaerobic digestion (configuration, retention time, operating temperature, quantity, and type of mixing); and co-generation (configuration, size and efficiency) are responsible for the difficulty in comparing sites.

Thermal hydrolysis simplifies the separation and processing of wastewater, thereby generating biogas and minimizing waste byproducts. Cambi ASA is one of the leading providers of thermal hydrolysis technology for sewage sludge treatment and organic waste management.

5. Microbial fuel cells

Microbial Fuel Cells (MFCs) are a relatively new technology that can treat wastewater and produce sustainable energy at the same time. The bacteria produce charged electrons during metabolism, which can be harnessed to generate electricity.

When it comes to the extraction and recovery of heavy metals from wastewater, MFCs have demonstrated exceptional efficiency. An algal-based MFC (Chlorella sp.) using nickel-foam/graphene electrodes was able to remove up to 95% of cadmium Cd(II) with a maximum adsorption quantity of 115 g/m2. With a maximum power density of 36.4 MW/m2, algae MFC offers superior power generation over competing technologies.

Similarly, functionalized adsorbents with high adsorption capabilities have been produced for the detection of metal pollutants in wastewater, including lead (Pb), copper (Cu), and cesium (Cs). Moreover, MFCs have produced clearance rates of Pb(II) and Cu2+ of 89.6% and 98.3%, respectively.

Even though MFCs offer many benefits, there are also substantial disadvantages to this technology that limit its adoption and growth in prospective fields. Several new technological developments have been made in this technology and have been demonstrated as an ecologically sustainable technology that generates energy while removing pollutants from different types of wastewater. However, due to its high cost, it has not been able to compete with its substitute technologies in the renewable energy sector or the wastewater treatment sector.

6. Membrane filtration

Membrane filtration is an evolving technology in the wastewater treatment sector that offers efficient removal of contaminants and enables water reuse. The innovation in membrane filtration includes the enhancement of membrane durability, reducing fouling, and improving energy efficiency.

Evove, which is a wastewater treatment technology company, recently won the World Changing Idea Award for Water Technology 2024. The company developed membranes that have overcome the inherent flaws in conventional membranes. Their new range of membranes has equal pore size distribution and consumes less energy.

ZwitterCo developed Zwitterionic membranes that perform better in high-foul environments, filtering out fats, oils, and proteins. Their technology significantly reduces cleaning and replacement costs.

Veolia, a leading wastewater treatment technology player, introduced the “Memthane anaerobic membrane bioreactor,” which treats heavily contaminated water and generates renewable energy through biogas production.

Similarly, companies like Evoqua Water Technologies, GE Water & Process Technologies, and Toray Industries have developed their membrane technology for the filtration of wastewater. The innovation is focused on low energy and chemical consumption.

7. Advanced Oxidation

Advanced oxidation processes (AOPs) can break down persistent organic contaminants in wastewater, making them more popular. AOPs and biological processes are being integrated in recent advancements to improve sustainability and efficiency. For instance, a recent study from 2023, emphasizes how biological therapies can be combined with solar photo-Fenton and photocatalysis to greatly enhance pollutant degradation while consuming the least amount of energy.

Another study discusses the use of non-conventional AOPs like microwave, ultrasound, and plasma pulse-assisted oxidation, which show promise for future applications due to their high efficiency and lower energy requirements. These advancements are necessary for addressing the increasing complexity of wastewater contaminants.

Several companies are at the forefront of these innovations; for instance, Veolia has launched advanced oxidation products that combine ozone and UV light to generate hydroxyl radicals, effectively treating various contaminants. Aquatech has introduced new AOP systems that integrate hydrogen peroxide and UV light, enhancing the degradation of organic pollutants. Xylem has also developed advanced oxidation solutions that utilize ozone and hydrogen peroxide, targeting industrial wastewater treatment.

8. Nanofiltration

Nanofiltration technology is a rapidly evolving technology for wastewater treatment. The recent innovations in nanofiltration technology have included enhanced membrane selectivity permeability and fouling resistance. “Recent Advances in the Theory and Application of Nanofiltration: a Review” by Yuchen DU, Biplob Kumar Pramanik highlights the development of thin film nanos composite membranes to incorporate materials like graphene oxide and metal-organic frameworks that significantly improve performance and durability. Another study shows the use of phase inversion and interfacial polymerization techniques that create more efficient nanofiltration membranes.

Several companies have recently launched new nanofiltration products, such as DuPont’s FilmTec LiNE-XD nanofiltration membrane which allows increased water and lithium recovery with reduced energy consumption.

TeraPore Technologies has developed IsoBlock virus filters leveraging their Intelligent Membrane platform. These filters provide high-resolution nanofiltration for bioprocessing applications with robust viral clearance and consistent performance.

SepPure Technologies provides advanced nanofiltration membranes tailored for diverse filtration requirements across industries, ensuring efficient separation and purification processes. Their technology particularly focuses on reducing the environmental impact of wastewater treatment.

Advancements in nanotechnology are driving the nanofiltration technology market.

9. Modular water treatment system

Modular water treatment systems are becoming popular due to their flexibility, scalability, and efficiency. These systems are designed to be easily transported and assembled, making them ideal for decentralized water treatment applications. New products are being designed in response to the increasing focus on improving the integration and modularity of modern treatment methods.

Several companies are developing modular water treatment solutions, and FCT Water Treatment offers custom modular systems that cater to various needs, including portable water, wastewater treatment, and groundwater remediation. The decentralized nature of modular water treatment systems significantly reduces the cost and minimizes jobsite work by allowing quick installation and commissioning.

Another company that specializes in modular wastewater treatment systems is Filtra Systems. It utilizes advanced technology to address distinct water treatment challenges. The company’s water treatment systems include Walnut Shell Filters (WNSF), dissolved air filtration, chemical management stations, pump stations, control valves, and several other instruments.

Some of the other prominent players that operate in modular water treatment systems are Genesis Water Technologies, Thermax Ltd, Veolia, etc.

10. Desalination

Desalination technology is essential in converting saline water into freshwater and addressing water scarcity in many regions around the world. The two primary methods used in desalination are thermal-based distillation and membrane-based filtration.

The current commercial technology used for desalination is reverse osmosis (RO), Multi-Effect Distillation, and Multi-stage Flash desalination (MSF).

MSF involves heating saline water and flushing it into steam in multiple stages and MED utilizes multiple steps of evaporation and condensation. These technologies are usually applied to large-scale desalination plants.

Several companies are developing technologies for desalination processes. Veolia is one of the leading players in desalination. The company’s latest product innovation in reverse osmosis (RO) technology delivers on-site ready-to-operate modules, It produces fresh water that complies with all water quality regulations while meeting the demands and challenges of the desalination business.
Additionally, low-pressure reverse osmosis (LPRO) and water reuse applications offer substantial savings on capital and operating costs which is a major challenge in water desalination.

Some of the prominent players in the desalination of wastewater include GE water, WABAG, and Aquatech, among others.